Multiply numbers step-by-step showing partial products, place value shifts, carries, and the final sum. Includes presets, a partial products table, carry visualization, and grid-method comparison.
The **Long Multiplication Calculator** breaks down multi-digit multiplication into clear, numbered steps — exactly the way you would solve it on paper. Enter any two whole numbers and instantly see every partial product, the place-value shift applied, any carries generated, and the final sum.
Long multiplication (also called the standard algorithm) works by multiplying the top number by each digit of the bottom number separately, shifting each partial product left by the appropriate number of places, and adding them all together. This calculator displays every stage in a detailed table so you can follow along, check homework, or teach the concept.
In addition to the standard method, the tool includes a grid (area/box) method breakdown that splits each factor into place-value components and shows the cross-products visually. This is the same approach used in many modern math curricula because it makes the distributive property explicit.
Carry digits are tracked and displayed for each partial product row, helping students see where regrouping happens. The final addition of partial products is shown with its own carry visualization. Presets range from simple single-digit products to challenging four-digit multiplications.
Output cards show the final product, the number of partial products, the largest carry generated, digit counts, and a decimal formatted result. Whether you are a student learning the algorithm or a teacher demonstrating the method, this calculator provides every detail in one place.
Long multiplication is useful when you want the place-value work behind the answer to stay visible.
It helps you verify carries, compare the standard algorithm with a grid method, and explain why each partial product contributes to the final sum. That makes it practical for homework checks, classroom demos, and any case where the process matters as much as the product.
a × b = Σ (a × bᵢ × 10ⁱ) for each digit bᵢ of b at position i
Result: 123 x 45 = 5,535.
Multiply 123 by 5 to get 615, then multiply 123 by 40 to get 4,920. Add the partial products to get 5,535.
Long multiplication works by turning one factor into a set of digit-by-digit products. Each row is a place-value shifted partial product, so the final sum is just the total of those aligned rows.
The carry is not a separate multiplication rule. It appears when the partial products are added together column by column. Watching the carry track makes it easier to see where the total changes.
The lattice or box method does not change the product. It reorganizes the same partial products into a rectangular grid, which helps when you want the distributive property made explicit.
Long multiplication is the standard paper-and-pencil algorithm for multiplying multi-digit numbers. You multiply by one digit at a time and add the shifted partial products.
Each partial product is the result of multiplying the entire multiplicand by a single digit of the multiplier, shifted left according to its place value. Adding all of those shifted rows together recreates the full product.
When the product of two digits exceeds 9, the tens digit is "carried" to the next column. For example, 7 × 8 = 56; write 6 and carry 5.
The grid method breaks each number into place-value parts (e.g. 23 = 20 + 3) and multiplies every pair. It is visually clearer but takes more writing.
This calculator works with whole numbers. For decimals, multiply as integers and then place the decimal point using the total number of decimal places.
The number of partial products equals the number of digits in the multiplier. A 3-digit × 4-digit problem has 4 partial products.